DE102012002206A1 - Buckle for safety seat belt, has safety mechanism, which has mass body that is movable in two opposite directions relative to lock housing and pivoted, multi-arm pivot lever, whose axis of rotation is immovable with respect to lock housing - Google Patents

Abstract

The buckle (10) has a lock housing (16), a locking mechanism, a release button (24) displaced relative to the lock housing, and a safety mechanism for preventing inertial, accidental shifting of the release button. The safety mechanism has a mass body (46) that is movable in two opposite directions relative to the lock housing and a pivoted, multi-arm pivot lever (26), whose axis of rotation is immovable with respect to the lock housing. A free arm (28) of the pivot lever is coupled to the release button.

Description

The invention relates to a buckle for a safety belt.

Especially with buckles, which are coupled to a belt tensioner, due to the strong acceleration at the beginning or end of a belt tightening, when large inertial forces act on the components of the buckle, the risk of inertial, unintentional opening of the buckle. Release locks, which are intended to prevent such unintentional opening of the buckle, are known in different design.

That's how it shows EP 0 557 983 A1 a seat belt buckle with a locking lock, in the case of high mass forces serving as a locking element locking pin is securely held in a locking position by its trajectory is blocked in a gate by a blocking element. The locking element is a rotatably mounted on the housing of the buckle pivot body which is movable with a free first arm in a locking position in which it secures the locking pin against movement from the locked position. The swivel body has an angled second arm for actuating and pivoting the swivel body by the release button of the buckle in a position releasing the locking pin. The second arm is connected at its free end to the release button via a slider-crank mechanism.

From the EP 0 823 223 A2 a buckle with the features of the preamble of claim 1 is known. In this buckle a on the housing of the buckle about a rotational axis pivotally mounted, multi-armed locking lever for preventing the inertia-related, unintentional displacement of the release button is provided. A first arm of the locking lever is hinged to the release button, while on a second arm, a pivoting body is movably mounted so that it transmits an inertial force to the second arm with abrupt speed change in one direction, wherein in the opposite direction by a movement relative to the second arm Power transmission from the swivel body is interrupted on the locking lever.

The object of the invention is to provide a buckle with a simple to integrate locking mechanism to prevent inertia-related, unintentional opening of the buckle, which works reliably and is inexpensive to produce.

This object is achieved by a buckle with the features of claim 1. Advantageous and expedient embodiments of the invention, the buckle are specified in the dependent claims.

The seatbelt buckle of the present invention comprises a buckle housing, a lock mechanism for locking a tongue inserted into the buckle, a release button slidable in a first direction relative to the buckle housing for unlocking the tongue, and a lock mechanism for preventing inadvertent, inadvertent movement of the buckle Release button in the first direction. According to the invention, the securing mechanism has a in the first direction and in a first direction opposite the second direction relative to the lock housing movable mass body. The securing mechanism further comprises a rotatably mounted, multi-arm pivot lever whose axis of rotation is immovable relative to the lock housing. A first free arm of the pivoting lever is coupled to the release button. A second free arm of the pivot lever is only in an acceleration of the buckle in the second direction in operative connection with the mass body.

The invention is based on the finding that unintentional opening of a buckle can be prevented by automatically opposing a counterforce in the closing direction of the release button (second direction) when a strong acceleration of an inertial force acting on the release button in the actuation direction (first direction) occurs becomes. For this purpose, the mass body and the pivot lever are provided according to the invention. The rotatable, but non-displaceable pivot lever ensures that the inertial forces acting on the free second arm and the mass body are transferred in the opposite direction to the release button. In this way, it can be prevented that the release button performs an undesirable shift in the direction of actuation.

In the case of an acceleration of the buckle in the first direction of the mass body according to the invention, however, is not in operative connection with the second free arm of the pivot lever. This means that the force acting on the mass body in the second direction inertial force is not transmitted via the pivot lever in the reverse direction (operating direction) on the release button. By decoupling the mass body from the pivot lever is thus ensured even with an acceleration of the buckle in the first direction that the release button can not be moved unintentionally in the direction of actuation.

The securing mechanism according to the invention requires only a few, simply kind Components, so that a largely trouble-free integration into a buckle without undue additional costs is possible.

For the purposes of the invention is meant a lock housing and a frame or other load-bearing structure. Furthermore, the term release button is intended to include any fixed components associated with it.

Particularly effective is the securing mechanism according to the invention in an embodiment in which the masses of the release button and the first free arm together are less than the sum of the masses of the second free arm, the mass body and any other components which in an acceleration of the buckle in the second Direction to exert a force on the second free arm in the first direction. In this case, with the same acceleration, the forces deflected and transferred to the release button in the closing direction are greater than the force of inertia acting directly on the release button in the direction of actuation. To prevent a shift of the release button then no additional measures are necessary.

The safety mechanism should of course not affect the normal use of the buckle. In order to ensure unhindered pressing of the release button in the actuation direction under normal conditions with inserted tongue of the seat belt, it is preferably provided that in a normal state of the buckle, in which the release button is relative to the lock housing in an extended position in the second direction, the Swivel lever is deflected by a manual operation of the release button in the first direction. Since under normal circumstances, no appreciable inertial forces act on the mass body and the second free arm of the pivot lever, these components exert no counterforce on the release button. Thus, a shift of the release button in the operating direction is basically permitted due to the deflectability of the pivot lever. However, this does not apply if - as described above - the buckle is strongly accelerated against the direction of actuation, since then automatically via the pivot lever an opposing force is transmitted to the release button.

In the preferred embodiment of the locking mechanism, the center of gravity of the pivoting lever is displaced eccentrically with respect to its axis of rotation in the direction of the second free arm and is preferably within the second free arm. The force of inertia acting on an acceleration of the pivot lever then generates an effective torque, which leads to the desired force reversal. The pivoting lever in this case acts as a rocker, which outputs an incoming pulse on the side of the pivoting lever on the side of the release button in the opposite direction.

The linear movements of the release button or the mass body in the operating direction to be converted by the pivot lever in linear movements of the mass body or the release button in the reverse direction. For this purpose, a construction is advantageous in which the first free arm of the pivot lever has a guide opening in the form of a slot or a backdrop into which a pin of the release button protrudes.

On the other side of the pivot lever, such a guide can best be realized by the fact that the second free arm has a guide opening in the form of a slot or a backdrop into which a guide pin only in the first and in the second direction relative to the lock housing slidable guide member protrudes. The guide element also serves a further purpose: since the guide element is pressed in the second direction due to its inertia against the second free arm of the pivot lever in the case of acceleration, this inertial force contributes in addition to generating the opposing force on the release button.

According to the preferred embodiment of the locking mechanism, the guide element is arranged between the second free arm and the mass body.

In the case of acceleration of the buckle in the first direction, the guide element coupled to the second free arm of the pivot lever must not absorb any force from the mass body. Therefore, the guide member should not be connected to the mass body to ensure the desired decoupling of the mass body from the pivot lever in such a situation.

In order to ensure, however, in the case of acceleration of the buckle in the first direction that the force acting on the mass inertial force is immediately available as a counterforce, the mass body should already assume a starting position in the normal state in which a power transmission is ensured on the pivot lever without delay. For this purpose, it is provided that the mass body is biased in the first direction against the second free arm by a compression spring, which is supported on a lock housing fixed portion. By a "lock housing fixed portion" is meant a portion which is either formed directly on the lock housing or immovable relative to the lock housing. The bias also serves as a resistor, which in the manual operation of the buckle to depress the release button is overcome. In addition, the bias ensures that the release button returns to the extended position in the second direction after releasing.

Further features and advantages of the invention will become apparent from the following description and from the accompanying drawings, to which reference is made. In the drawings show:

1 an exploded view of a buckle according to the invention;

2 a perspective view of the buckle in the normal state;

3 a side view of the buckle in the normal state;

4 one opposite the view in the 3 and 4 rotated 90 ° side view of the buckle in the normal state;

5 a perspective view of the buckle while holding the release button;

6 one opposite the view in the 3 rotated 90 ° side view of the buckle while holding the release button; and

7 a perspective view of the buckle during acceleration in a first direction.

In the figures is a buckle 10 illustrated for a safety belt system, which is fixed to the vehicle via a fitting, not shown, either directly or with a belt tensioner connected to the fitting. The housing shells 12 . 14 are in the 2 to 7 omitted to look at the internal components of the buckle 10 release. From the in 1 shown components will be discussed below only on the components relevant to the invention, since the basic structure and the basic operation of a buckle are assumed to be known.

On a load-bearing lock housing 16 is a locking cam guide 18 firmly mounted. Two compression springs 20 . 22 clamp a slide-like trained and relative to the lock housing 16 only in the directions A and B sliding release button 24 in the second direction B (closing direction) which is opposite to the first direction A (operating direction).

A two-armed swivel lever 26 is rotatable about a rotation axis C on the lock housing fixed locking cam guide 18 stored. The swivel lever 26 has two free arms 28 . 30 which extend substantially diametrically from the axis of rotation C. The second free arm 30 has a much larger mass than the rest of the swing lever 26 , The swivel lever 26 has accordingly with respect to its axis of rotation C eccentric center of gravity, ideally within the second arm 30 lies.

Both free arms 28 . 30 of the pivot lever 26 have a guide opening 32 respectively. 34 in the form of a long hole. in the first guide hole 32 of the first free arm 28 a pen sticks out 36 the release button 24 , In the second guide hole 34 of the second free arm 30 sticks out a guide pin 38 a guide element 40 , The guide element 40 is like the release button 24 only in the directions A and B relative to the lock housing 16 slidably mounted.

A stop surface 42 of the guide element 40 lies a counter-attack surface 44 a separate mass body 46 directly opposite. The mass body 46 is as well as the guide element 40 and the release button 24 only in the directions A and B relative to the lock housing 16 slidably mounted. The mass body 46 is through the first compression spring 20 whose first end in the second direction B on the lock housing fixed locking cam guide 18 and its opposite second end on the mass body 46 is present, in the first direction A against the guide element 40 and thus against the second free arm 30 of the pivot lever 26 biased. The guide element 40 and the mass body 46 But they are not connected.

The masses of the release button 24 (including any components attached to it) and the first free arm 28 of the pivot lever 26 together are larger than the mass of the second free arm 30 of the pivot lever 26 , but less than the sum of the masses of the second free arm 30 , the guide element 40 and the mass body 46 ,

In the normal condition of the buckle 10 in the 2 to 4 is shown, is the release button 24 not pressed and is located relative to the lock housing 16 in a position extended in the second direction B. By pressing the release button 24 in the first direction A against the biasing force of the compression springs 20 . 22 can one in the buckle 10 inserted and by a locking mechanism, here a locking cam mechanism, locked tongue of a safety belt (not shown) are unlocked. On the locking mechanism will not be discussed, since its specific embodiment is not relevant to the invention.

The condition of the buckle 10 while holding down the release button 24 is in the 5 and 6 shown. The shift of the release button 24 relative to the lock housing 16 in the first direction A leads due to the coupling via the in the first guide opening 32 protruding pen 36 the release button 24 to a deflection of the first free arm 28 of the pivot lever 2 , as shown in the 4 and 6 counterclockwise. The rotation of the lock housing fixed locking cam guide 18 rotatably mounted pivot lever 24 in turn leads to a deflection of the guide element 40 and of the adjoining mass body 46 in the second direction B, against the biasing force of the compression spring 20 , The pencils 36 and 38 the release button 24 or of the guide element 40 as well as the guide holes designed as slots 32 and 34 of the pivot lever 26 are coordinated so that the linear movement of the release button 24 in the first direction A in a linear movement of the guide element 40 and the mass body 46 in the second direction B is converted. As long as in the direction A no significant force on the mass body 46 , the guiding element 40 or the second free arm 30 of the pivot lever 26 acts, the movement of the release button 24 not significantly impeded in the direction A.

Starting from the normal state of the buckle 10 with inserted tongue and not pressed release button 24 should now be the case of a strong acceleration of the buckle 10 be considered in the second direction B, as in particular when braking the buckle 10 at the end of a belt tightening process or as a result of a hard impact on the floor of the vehicle, which is on the belt buckle 10 transmits, can occur. In this case act on all components of the buckle 10 Inertia forces in the first direction A. A movement of the release button 24 in this direction, which could have an unlocking of the tongue result, but is prevented, as explained below.

The total on the mass body 46 , the guiding element 40 and the second free arm 30 of the pivot lever 26 acting inertial force in the first direction A is by the rotatably mounted, but relative to the lock housing 16 non-displaceable pivot lever 26 about his first free arm 28 and the pen 36 in the second direction B on the release button 24 transfer, as best of the 2 and 4 results. Because the mass body 46 , the guiding element 40 and the second free arm 30 of the pivot lever 26 together heavier than the release button 24 and the first free arm 28 of the pivot lever 26 these are in direction B on the release button 24 transmitted force greater than that in the direction A on the release button 24 acting inertial force. Thus, the buckle 10 safely held in the locked state.

The 7 shows the buckle 10 with a strong acceleration in the direction A, as can occur especially at the beginning of a belt tensioning process. In this case, the B direction acts on the release button 24 acting inertial force only a force that is less than this inertial force. Because the mass body 46 neither with the second free arm 30 of the pivot lever 26 still with the guide element 40 is connected, the mass body couples 46 from this composite. Thus, only the sum of the second free arm 30 and the guide element 40 acting inertial forces over the first free arm 28 and the pen 36 in the first direction A on the release button 24 transferred, but not on the mass body 46 acting inertial force. Due to the above-described mass ratios, this counterforce is not sufficient to the release button 24 to move in the first direction A.

It is also an embodiment of the locking mechanism described above possible without the guide element 40 gets along, z. B. by the additional mass body 46 at an acceleration in the second direction B directly to the second free arm 30 of the pivot lever 26 acts. In this case, the masses of the release button 24 (including any components attached to it) and the first free arm 28 of the pivot lever 26 together larger than the mass of the second free arm 30 but less than the sum of the masses of the second free arm 30 and the mass body 46 ,

LIST OF REFERENCE NUMBERS

10

buckle

12

shell

14

shell

16

lock housing

18

Locking cam guide

20

first compression spring

22

second compression spring

24

release button

26

pivoting lever

28

first free arm

30

second free arm

32

first guide opening

34

second guide opening

36

pen

38

guide pin

40

guide element

42

stop surface

44

Thrust face

46

mass body

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 0557983 A1 [0003]
• EP 0823223 A2 [0004]

Claims (9)

Buckle ( 10 ) for a safety belt, with a lock housing ( 16 ), a locking mechanism for locking a in the lock housing ( 16 ) inserted tongue, a release button ( 24 ) in a first direction A relative to the lock housing ( 16 ) is displaceable for unlocking the tongue, and a securing mechanism for preventing an inertial, unintentional displacement of the release button ( 24 ) in the first direction A, characterized in that the securing mechanism has a second direction B, which is opposite in the first direction A and in the first direction A, relative to the lock housing (FIG. 16 ) movable mass body ( 46 ) and a rotatably mounted, multi-arm pivoting lever ( 26 ) whose axis of rotation C relative to the lock housing ( 16 ) is immobile, with a first free arm ( 28 ) of the pivoting lever ( 26 ) to the release button ( 24 ) and a second free arm ( 30 ) of the pivoting lever ( 26 ) only with an acceleration of the buckle ( 10 ) in the second direction B in operative connection with the mass body ( 46 ) stands. Buckle ( 10 ) according to claim 1, characterized in that the masses of the release button ( 24 ) and the first free arm ( 28 ) together are less than the sum of the masses of the second free arm ( 30 ), the mass body ( 46 ) and any other components which are in an acceleration of the buckle ( 10 ) in the second direction B a force on the second free arm ( 30 ) in the first direction A. Buckle ( 10 ) according to claim 1 or 2, characterized in that in a normal state of the buckle ( 10 ), in which the release button ( 24 ) relative to the lock housing ( 16 ) is in an extended position in the second direction B, the pivot lever ( 26 ) by a manual operation of the release button ( 24 ) in the first direction A is deflectable. Buckle ( 10 ) according to one of the preceding claims, characterized in that the center of gravity of the pivot lever ( 26 ) with respect to its axis of rotation C eccentrically in the direction of the second free arm ( 30 ) and preferably within the second free arm ( 30 ) lies. Buckle ( 10 ) according to one of the preceding claims, characterized in that the first free arm ( 28 ) a guide opening ( 32 ) in the form of a slot or a backdrop into which a pin ( 36 ) of the release button ( 24 protrudes. Buckle ( 10 ) according to one of the preceding claims, characterized in that the second free arm ( 30 ) a guide opening ( 32 ) in the form of a slot or a backdrop into which a guide pin ( 38 ) one only in the first direction A and in the second direction B relative to the lock housing ( 16 ) sliding guide element ( 40 protrudes. Buckle ( 10 ) according to claim 6, characterized in that the guide element ( 40 ) between the second free arm ( 30 ) and the mass body ( 46 ) is arranged. Buckle ( 10 ) according to claim 6 or 7, characterized in that the guide element ( 40 ) not with the mass body ( 46 ) connected is. Buckle ( 10 ) according to one of the preceding claims, characterized in that the mass body ( 46 ) by a compression spring ( 20 ), which is supported on a lock housing fixed portion, in the first direction A against the second free arm ( 30 ) is biased.

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